Follow the smell of the ocean to find where marine predators feed

0

IMAGE

The chemical DMSP is released when phytoplankton are consumed by zooplankton such as krill.

A joint research project between organizations in Japan and the US has demonstrated that zooplankton, a major food source for marine predators, can be located by following the concentration gradient of the chemical dimethyl sulfide (DMS) in ocean water and air. Currently, little is known about how marine predators search for and find enough food to maintain their body size. This study is expected to expand research into the chemical triggers of marine organisms while foraging.

Zooplankton, such as krill and copepods are the main energy source for many large marine animals. The big predators must consume a large amount of these tiny creatures to provide enough energy to power their enormous bodies. How they find their food is still not clearly understood.

Krill feed on phytoplankton which produce and retain water-soluble compounds in their bodies to cope with osmotic pressure. This is essential for survival in seawater. One of these compounds is dimethylsulfoniopropionate (DMSP). DMSP contains sulfur elements and is zwitterionic, meaning that it has both a positive and a negative charge like an amino acid. It is broken down by bacteria into DMS, a component of the familiar aromas associated with ocean air or dried seaweed. DMSP stored in phytoplankton is released into seawater when zooplankton graze on the phytoplankton, which is hypothesized to result in higher DMS concentrations in dense zooplankton areas. It is thought that marine predators could use DMS concentration to locate food sources. While attraction to artificially released DMS has been shown in some predatory species, whether natural gradients of DMS are used by predators and serve as a useful foraging cue remains unknown.

To investigate the phenomenon, an international team of researchers from Kumamoto University and Woods Hole Oceanographic Institution developed a new instrument to continuously and automatically analyze seawater and atmospheric concentrations of DMS. Together with a researcher from Stony Brook University, they then used the device to conduct a survey in June 2019 off the coast of Cape Cod, Massachusetts, a summer feeding grounds for many baleen whale species. Researchers took chemical measurements, recorded zooplankton and fish biomass, and whale locations over a series of transects across the ocean surface.

Their work revealed that, as hypothesized, zooplankton grazing on phytoplankton seems to result in higher localized concentrations of DMS compared to surrounding areas. In contrast, no association was found between fish biomass and DMS concentration. Simulations based on their measurements show that if large marine predators, such as whales, are able to detect the DMS concentration gradient, following increasing concentrations of DMS would allow them to reach denser zooplankton feeding areas than if they swam randomly.

“We plan to expand this research project in the future to investigate the relationship between DMS and predation by measuring the concentration of the chemical alongside marine predator movement trajectories,” said Professor Kei Toda, who led the chemical measurements. “We also plan to explore other attractant chemicals and study their relationship with the behavior of marine predators like whales, seabirds and penguins. A pilot study tagging humpback whales to examine their movements in relation to DMS was conducted in Antarctica in February 2020, but there are still some issues that need to be addressed to pursue the relationship between chemical substances and predation. We believe that we will have some interesting findings in the near future.”

###

This research was posted online in Communications Biology on 1 February 2021.

Source:

K. Owen, K. Saeki, J. D. Warren, A. Bocconcelli, D. N. Wiley, S.-I. Ohira, A. Bombosch, K. Toda, and D. P. Zitterbart, “Natural dimethyl sulfide gradients would lead marine predators to higher prey biomass,” Communications Biology, vol. 4, no. 149, Feb. 2021.

Media Contact
J. Sanderson & N. Fukuda
[email protected]

Related Journal Article

http://dx.doi.org/10.1038/s42003-021-01668-3

Leave A Reply

Your email address will not be published.